乳腺癌中p16INK4a和视网膜母细胞瘤基因甲基化状况及其表达

目的 研究乳腺癌及癌旁增生组织中p16INK4a和视网膜母细胞瘤(RB)基因启动子区域的甲基化状况,并探讨基因异常甲基化与蛋白表达及其临床意义.方法 采用甲基化特异性PCR方法 对46例乳腺癌、22例癌旁增生组织及7例正常乳腺组织中p16INK4a和RB基因启动子区域甲基化状况进行检测,并采用免疫组织化学SP法对p16INK4a蛋白表达情况进行相应检测.结果 乳腺癌、癌旁增生组织和正常乳腺组织中p16INK4a基因的甲基化率分别为23.9%(11/46)、18.2%(4/22)、1/7;RB基因的甲基化率分别为10.8%(5/46)、9.1%(2/22)、0(0/7);肿瘤组织、癌旁增生组织和正常乳腺组织中p16INK4a基因、RB基因甲基化率差异均无统计学意义(P>0.05).正常乳腺组织、癌旁增生组织、乳腺癌中p16INK4a蛋白表达阳性率分别为7/7、60.8%(28/46)和81.8%(18/22),三者之间差异无统计学意义(P>0.05);肿瘤组织中p16INK4a蛋白表达与肿瘤分级相关(P<0.05);肿瘤组织中p16INK4a甲基化状况与其蛋白表达、肿瘤分级、ER表达阴性具有相关性(P<0.05),与肿瘤大小、淋巴结转移、年龄均不相关;RB基因甲基化状态与肿瘤分级、肿瘤大小、ER表达及年龄均无相关性,但与淋巴结转移相关(P<0.05).结论 p16INK4a基因异常甲基化可能在乳腺癌发生过程中作用有限,但在肿瘤的演进中发挥作用;RB基因甲基化检测对于分析乳腺癌进展及预后情况可能有一定参考价值;p16INK4a基因甲基化是p16INK4a蛋白失表达的机制之一.     

乳腺癌中p16INK4a和视网膜母细胞瘤基因甲基化状况及其表达

目的 研究乳腺癌及癌旁增生组织中p16INK4a和视网膜母细胞瘤(RB)基因启动子区域的甲基化状况,并探讨基因异常甲基化与蛋白表达及其临床意义.方法 采用甲基化特异性PCR方法 对46例乳腺癌、22例癌旁增生组织及7例正常乳腺组织中p16INK4a和RB基因启动子区域甲基化状况进行检测,并采用免疫组织化学SP法对p16INK4a蛋白表达情况进行相应检测.结果 乳腺癌、癌旁增生组织和正常乳腺组织中p16INK4a基因的甲基化率分别为23.9%(11/46)、18.2%(4/22)、1/7;RB基因的甲基化率分别为10.8%(5/46)、9.1%(2/22)、0(0/7);肿瘤组织、癌旁增生组织和正常乳腺组织中p16INK4a基因、RB基因甲基化率差异均无统计学意义(P>0.05).正常乳腺组织、癌旁增生组织、乳腺癌中p16INK4a蛋白表达阳性率分别为7/7、60.8%(28/46)和81.8%(18/22),三者之间差异无统计学意义(P>0.05);肿瘤组织中p16INK4a蛋白表达与肿瘤分级相关(P<0.05);肿瘤组织中p16INK4a甲基化状况与其蛋白表达、肿瘤分级、ER表达阴性具有相关性(P<0.05),与肿瘤大小、淋巴结转移、年龄均不相关;RB基因甲基化状态与肿瘤分级、肿瘤大小、ER表达及年龄均无相关性,但与淋巴结转移相关(P<0.05).结论 p16INK4a基因异常甲基化可能在乳腺癌发生过程中作用有限,但在肿瘤的演进中发挥作用;RB基因甲基化检测对于分析乳腺癌进展及预后情况可能有一定参考价值;p16INK4a基因甲基化是p16INK4a蛋白失表达的机制之一.     

脑膜瘤 p16INK4a、RB基因的甲基化分析及对基因表达的影响

目的　检测脑膜瘤中发生 p16 INK4 a和 RB基因甲基化的情况及对蛋白表达的影响。方法　用甲基化特异性聚合酶链反应对 5 0例脑膜瘤进行了 p16 INK4 a和 RB的甲基化分析 ;并对其中的 2 5例检测了p16 INK4 a蛋白的表达。结果　良性脑膜瘤中没有检测到甲基化 ,分别有 6例 级 ( 37.5 % )和 4例 级( 2 8.6 % )肿瘤发生至少一种基因的甲基化 ,其中有 1例不典型脑膜瘤同时发生了两种基因的甲基化。全部13例 p16 INK4 a阳性表达的肿瘤都是没有检测到甲基化者。结论　p16 INK4 a或 RB的甲基化与不典型和间变性脑膜瘤的发生发展有关 ,其机制可能是甲基化使蛋白表达丢失并导致 p16 INK4 a/细胞周期蛋白 D1/ CDK4 /RB途径功能障碍     

散发性乳腺癌及乳腺不典型导管增生组织BRCA1基因启动子区甲基化分析

目的 了解散发性乳腺癌及癌旁增生组织、乳腺不典型导管增生组织BRCA1基因启动子区甲基化状态,探讨其与乳腺癌发生的关系.方法 采用甲基化特异性PCR(MSP)结合巢式PCR技术,研究23例散发性乳腺癌及其癌旁增生组织、6例乳腺不典型导管增生组织及5例健康成人女性外周血淋巴细胞中BRCA1基因启动子区甲基化状态.结果 5例健康成人女性外周血淋巴细胞均表现BRCA1基因启动子区甲基化阴性;23例原发性乳腺癌组织中,BRCA1基因启动子区CpG岛甲基化率为65.22%(15/23);癌旁增生组织检出CpG岛甲基化者11例,甲基化率为47.83%(11/23),且均为癌组织阳性患者;6例乳腺不典型导管增生组织中,BRCA1基因启动子区CpG岛甲基化阳性者2例,甲基化率为33.33%(2/6);统计学检验结果表明,乳腺癌、癌旁增生组织之间,BRCA1基因启动子区甲基化阳性率无显著差异.结论 BRCA1基因启动子区CpG 岛甲基化是散发性乳腺癌发生过程中的早期事件,可能在乳腺癌发生中和乳腺增生病癌变过程中起重要生物学作用.     

胃癌中p16INK4a基因启动子高甲基化及其蛋白表达

目的探讨胃癌中p16^INK4a基因失活的主要分子机制及其与胃癌发生、发展的关系。方法采用甲基化特异性PCR技术检测62例胃癌和癌旁组织及10例慢性胃炎黏膜p16^INK4a基因启动子区CpG岛甲基化状态,用免疫组化EnVision两步法检测p16^INK4a蛋白的表达。结果62例胃癌和癌旁组织p16^INK4a基因启动子高甲基化率分别为51．6％（32／62）和19.4％（12／62）,10例正常对照胃黏膜未发现高甲基化,胃癌组织p16^INK4a基因启动子高甲基化率高于癌旁组织和正常对照（P〈0．05）。58.1％（36／62）的胃癌组织p16^INK4a蛋白表达阴性,其中72.2％（26／36）的病例具有p16^INK4a基因启动子的高甲基化,p16^INK4a基因启动子的高甲基化与其蛋白失表达密切相关（P〈0.05）。结论胃癌中p16^INK4a基因启动子的高甲基化是p16^INK4a基因失活的主要机制,并可能是胃癌发生中的早期分子事件。     

食管鳞状细胞癌中p16基因甲基化及其表达

目的：探讨食管鳞状细胞癌p16／INK4基因启动子区高甲基化和p16、cyclinD1蛋白表达的意义。方法：用甲基化特异性PCR（MSP）法检测p16／INK4基因启动子区的高甲基化，用免疫组织化学方法检测p16、cyclind1蛋白的表达。结果：30例食管鳞状细胞癌中7例p16免疫组织化学阳性，15例cyclinD1阳性，组织学和统计学分析显示p16与cyclinD1的表达呈负相关。4例检出p16／INK4基因启动子区高甲基化，但与p16失表达无统计学意义。结论：（1）在食管鳞状细胞癌可检出p16／INK4基因启动子区的高甲基化，而甲基化不是引起p16失表达的主要原因。（2）p16与cyclinD1的表达呈负相关，提示细胞周期调控因子之间可能存在相互影响表达的反馈机制。     

骨髓增生异常综合征与白血病细胞p15INK4B基因甲基化及机制研究

目的:探讨p15INK4B基因甲基化异常和血液系统肿瘤发病的关系及甲基化异常的机制。方法:采用RT-PCR、甲基化特异PCR、Western blot法检测20例骨髓增生异常综合征(MDS)、20例急性白血病患者(AL)、14例慢性粒细胞性白血病(CML)患者骨髓单个核细胞p15INK4B基因 mRNA和p15INK4B蛋白的表达、p15INK4B基因甲基化及甲基转移酶(DNMTs)的表达。结果:高危组MDS患者p15INK4B蛋白表达阳性率低于低危组MDS患者(10% vs 80%,P<0.01),p15INK4B基因甲基化阳性率较高(60% vs 10%,P<0.01)。20例AL有9例(45%)存在p15INK4B基因甲基化。10例CML慢性期(CML-CP)患者仅1例存在p15INK4B基因甲基化。4例CML急变期(CML-BP)患者均检测到p15INK4B基因部分甲基化。DNMT_3A、DNMT_3B表达在AL、高危组MDS和CML-BP患者均明显高于低危组MDS(P<0.05)。结论:p15INK4B基因甲基化在AL、高危组MDS和CML-BP患者发生率高于低危组MDS,伴有甲基转移酶DNMT_3A、DNMT_3B表达较高。p15INK4B基因甲基化可能参与MDS和AL的发病机制并与MDS 及CML的预后有关。     

乳腺增生病p53基因第5外显子突变及其蛋白表达

目的：探讨p53基因在乳腺癌发生早期的作用。方法：用免疫组化方法检测36例乳腺单纯性增生、31例不典型增生、14例原位癌和16例浸润癌中p53蛋白的表达，用PCR－SSCP检测了上述组织中p53基因第5外显子突变。结果：p53蛋白在单纯性增生、不典型增生、导管内癌、浸润癌中的表达率分别为0、22.6%(7/31)、42.8%(6/14)、50％（8／16），PCR－SSCP在各组中均未检测到该基因第5外显子突变。结论：乳腺癌发生早期阶段有p53基因的参与，但与第5外显子突变无明显关系。     

乳腺癌中印记基因SLC22A18/TSSC5/BWR1A启动子区甲基化及mRNA表达的研究

目的： 研究印记基因SLC22A18启动子区甲基化对乳腺侵润性导管癌组织中的SLC22A18 mRNA表达的影响，探讨其与临床病理特征之间的关系。方法：实时荧光定量逆转录聚合酶链反应（real-time quantitative RT-PCR）方法检测40例乳腺侵润性导管癌及其癌旁组织中SLC22A18 mRNA的表达，甲基化特异性聚合酶链反应(MSP)检测SLC22A18基因启动子区的甲基化状态。检测DNA甲基转移酶抑制剂5-氮杂-2′-脱氧胞苷（5-aza-2′-deoxycytidine，5-aza-dc）和组蛋白去乙酰化酶抑制剂曲古霉素A（TSA）作用于乳腺癌细胞株MDA-MB-231后，对SLC22A18基因启动子区DNA甲基化和mRNA表达的影响。结果：SLC22A18在40例乳腺侵润性导管癌中mRNA表达量低于癌旁组织（0.12±0.10 vs 0.69±1.05，P＜0.01）；40例乳腺侵润性导管癌及对应癌旁组织中，SLC22A18启动子区的甲基化发生率分别为75％和37.5%，差异有统计学意义（P＜0.01）；在40例乳腺侵润性导管癌组织中，甲基化组SLC22A18 mRNA表达量低于非甲基化组（0.11±0.08 vs 0.24±0.18，P＜0.01）。5-aza-dc和5-aza-dc/TSA能不同程度逆转乳腺癌细胞株MDA-MB-231中SLC22A18基因的甲基化状态，并上调SLC22A18基因表达。结论：SLC22A18基因甲基化与乳腺癌发生有一定的关联，SLC22A18基因表达下调与其启动子区CpG岛异常甲基化相关。     

银屑病患者皮损p16INK4a基因CpG甲基化位点和频度

目的研究皮损表皮p16INK4a甲基化阳性的银屑病患者基因启动子区CpG甲基化的位点和频度。方法采集50例银屑病患者皮损处皮肤,分离表皮,提取DNA。采用甲基化特异性PCR和测序法检测p16INK4a基因启动子区CpG甲基化的位点和频度。结果p16INK4a基因启动子甲基化阳性的患者,约50%CpG发生甲基化,均出现于特定位点。结论p16INK4a甲基化阳性银屑病患者p16INK4a基因启动子并非完全发生甲基化。     

脑膜瘤P16^INK48、RB基因的甲基化分析及对基因表达的影响

目的 检测脑膜瘤中发生P16^INK48和RB基因甲基化的情况及对蛋白表达的影响。方法 用甲基化特异性聚合酶链反应对50例脑膜瘤进行了P16^INK48和RB的甲基化分析；并对其中的25例检测了P16^INK48蛋白的表达。结果 良性脑膜瘤中没有检测到甲基化，分别有6例ⅡⅢ级(37．5％)和4例Ⅲ级(28．6％)肿瘤发生至少一种基因的甲基化，其中有1例不典型脑膜瘤同时发生了两种基因的甲基化。全部13例P16^INK48阳性表达的肿瘤都是没有检测到甲基化者。结论 P16^INK48或RB的甲基化与不典型和间变性脑膜瘤的发生发展有关，其机制可能是甲基化使蛋白表达丢失并导致P16^INK48细胞周期蛋白D1／CDK4／RB途径功能障碍。     

Promoter methylation status of multiple genes in brain metastases of solid tumors

The aberrant methylation of the CpG island promoter regions acquired by tumor cells is one mechanism for loss of gene function. The high methylation rate for RB1 and death-associated protein-kinase gene (DAP-kinase) (60 and 90%, respectively) previously found in brain metastases suggests this mechanism could be non-randomly associated to tumor progression and metastasis. Thus, in addition to these two genes, we determined the methylation status of the genes p16INK4a, glutathione S-transferase P1 (GSTP1), O6-methylguanine DNA methyltransferase (MGMT), thrombospondin-1 (THBS1), p14ARF, TP53, p73, and tissue inhibitor of metalloproteinase 3 (TIMP-3), in 18 brain metastases of solid tumors, with methylation specific PCR. The metastases were derived from malignant melanoma (three cases), lung carcinoma (six cases), breast carcinoma (three cases), ovarian carcinoma (two cases) and one each from colon, kidney, bladder and undifferentiated carcinoma. We detected methylation levels in the tumor samples of 83% in p16INK4a, 72% in DAP-kinase, 56% in THBS1, 50% in RB1, 39% in MGMT, 33% in GSTP1 and p14ARF each, 22% in p73 and TIMP-3 each, and 11% in TP53. The methylation index (number of genes methylated/number of genes tested) varied between 0.1 and 0.6, with an average of 0.42, indicating that a high grade of gene methylation accumulates parallel to the tumor metastasis process. Our data suggest an important role for gene methylation in the development of brain metastases, primarily involving epigenetic silencing of DAP-kinase, THBS1 and the cell-cycle regulators RB1/p16INK4a.     

Molecular analysis of the INK4A and INK4B gene loci in human breast cancer cell lines and primary carcinomas

The INK4A and INK4B loci are located at 9p21 and have been implicated in the tumorigenesis of various human malignancies. The INK4A gene encodes two cell cycle regulators, p16(INK4A) and ARF, while INK4B encodes p15(INK4B). Previously, we have shown that the p16(INK4) tumor suppressor was not mutated or deleted in primary breast carcinomas. However, primary and metastatic breast carcinomas exhibited a relative hypomethylation of p16(INK4A), which is associated with expression, compared to normal breast tissue. The present study was conducted to determine if inactivation of p15(INK4B) and INK4A exon 1beta (ARF) are common events in breast carcinoma. Mutational analysis was performed by PCR-SSCP, and mRNA expression was evaluated by RT-PCR. Methylation-specific PCR was used to determine the methylation status of the p15(INK4B) promoter. Our results demonstrate that the p15(INK4B) gene was altered in 3 (21%) of the 14 breast cell lines; one had a silent mutation and two had homozygous deletion of the gene. None of the cell lines showed methylation of p15(INK4B). Two (14%) cell lines had homozygous deletion of INK4A exon 1beta. All normal and malignant breast tissue samples were wild-type and non-methylated for p15(INK4B) and wild-type for exon 1beta. Our results show that these structurally and functionally related genes are not invariably affected together, and the most frequently observed alteration at the INK4A and INK4B loci in breast carcinoma appears to be p16(INK4A) hypomethylation.     

Prognostic value of p16INK4a and p14ARF gene hypermethylation in human colon cancer

The INK4a/ARF locus (9p21) encodes two unique and unrelated cell cycle regulators, p16INK4a and p14ARF. This study was performed to evaluate the methylation status of p16INK4a and p14ARF genes, as well as its association with p16 and p53 expression, microsatellite instability (MI) status, and various clinicopathologic parameters in sporadic colorectal cancer. Sixty-five cases of primary colorectal adenocarcinoma with a series of clinicopathological parameters were obtained. We performed methylation-specific PCR of p16INK4a and p14ARF genes in colorectal cancer paraffin blocks with its paired normal samples, as well as immunohistochemical stainings for p16 and p53, and MI analysis. Aberrant methylations of p16INK4a and p14ARF gene were present in 21 (32.3%) and 33 (50.8%) out of 65 cases, respectively. p16INK4a aberrant methylation was correlated with p16 negativity (P=0.021) and p53 overexpression (P=0.007). p16INK4a aberrant methylation was more frequently present in poorly differentiated adenocarcinomas (P=0.002). Aberrant methylation of p14ARF gene occurred more frequently in patients under 50 years of age and in left-sided colon cancers, and was not statistically significant. Compared with the group with simultaneous absence of methylation in both promoters, the group showing concomitant alterations in both p16INK4a and p14ARF genes (n=10) more frequently presented lymph node metastasis (P=0.020) and higher tumor grade (P=0.014). There was no correlation between p16INK4a and p14ARF gene hypermethylation or MI status. This study suggests that simultaneous hypermethylation of both p16INK4a and p14ARF genes is greater prognostic value in sporadic human colorectal cancer.     

Detection of aberrant p16INK4A methylation in sera of patients with liver cirrhosis and hepatocellular carcinoma

Hepatocellular carcinomas (HCCs) show genomic alterations, including DNA rearrangements associated with HBV DNA integration, loss of heterozygosity, and chromosomal amplification. The genes most frequently involved are those encoding tumor suppressors. The p16INK4A tumor suppressor gene frequently displays genetic alteration in HCC tissues. The present study was performed to examine the incidence of methylated p16INK4A in the sera of liver cirrhosis (LC) and HCC patients, and to evaluate its role as a tumor marker of HCC. The sera of 23 LC patients and 46 HCC patients were examined in this study. The methylation status of p16INK4A was evaluated by methylation-specific PCR of serum samples. Methylated p16INK4A was detected in 17.4% (4/23) of LC patients and in 47.8% (22/46) of HCC patients. No association was demonstrated between p16INK4A methylation and serum AFP level. As the status of p16INK4A methylation was not associated with serum AFP level, it may have a role as a tumor marker of HCC.     

Combined analysis of p53 and RB pathways in epithelial ovarian cancer

Disruptions of the p16-CDK4/cyclin D1-pRb pathway (RB pathway) and the p14ARF-MDM2-p53 pathway (p53 pathway) are important mechanisms in the development of human malignancies. In this study, we investigated RB and p53 pathways in 46 epithelial ovarian cancers (EOCs). In the RB pathway, 16 (34.8%) of 46 cases had p16 gene alterations or loss of expression. The deletion of the p16 gene was a rare event. In 7 cases, we observed methylation in the 5'CpG island in the promoter region of the p16 gene. Abnormal expressions of pRb and CDK4/cyclin D1 were 10.9% and 30.4%, respectively. In the p53 pathway, 10 (21.7%) of 46 cases had p14ARF gene alterations or abnormal expression. In 4 cases, methylation in the 5'CpG island in the promoter region of the p14ARF gene was present. MDM2 overexpression was a rare event. Thirty-six (78.3%) of 46 patients had p53 gene alterations or expression. In our studied cases, p14ARF abnormalities were independent of p16 abnormalities. Abnormal RB and p53 pathways were present in 60.9% and 80.4% of cases, respectively. In conclusion, disruptions of p53 and RB pathways are frequent events and the inverse correlations were present between the abnormality of p16 and p14ARF in EOCs.     

Loss of p16/INK4A Protein Expression in Non-Hodgkin’s Lymphomas Is a Frequent Finding Associated with Tumor Progression

The CDKN2A gene located on chromosome region 9p21 encodes the cyclin-dependent kinase-4 inhibitor p16/INK4A, a negative cell cycle regulator. We analyzed p16/INK4A expression in different types of non-Hodgkin’s lymphoma to determine whether the absence of this protein is involved in lymphomagenesis, while also trying to characterize the genetic events underlying this p16/INK4A loss. To this end, we investigated the levels of p16/INK4A protein using immunohistochemical techniques in 153 cases of non-Hodgkin’s lymphoma, using as reference the levels found in reactive lymphoid tissue. The existence of gene mutation, CpG island methylation, and allelic loss were investigated in a subset of 26 cases, using single-strand conformational polymorphism and direct sequencing, Southern Blot, polymerase chain reaction, and microsatellite analysis, respectively. Loss of p16/INK4A expression was detected in 41 of the 112 non-Hodgkin’s lymphomas studied (37%), all of which corresponded to high-grade tumors. This loss of p16/INK4A was found more frequently in cases showing tumor progression from mucosa-associated lymphoid tissue low-grade lymphomas (31 of 37) or follicular lymphomas (4 of 4) into diffuse large B-cell lymphomas. Analysis of the status of the p16/INK4A gene showed different genetic alterations (methylation of the 5′-CpG island of the p16/INK4A gene, 6 of 23 cases; allelic loss at 9p21, 3 of 16 cases; and nonsense mutation, 1 of 26 cases). In all cases, these events were associated with loss of the p16/INK4A protein. No case that preserved protein expression contained any genetic change. Our results demonstrate that p16/INK4A loss of expression contributes to tumor progression in lymphomas. The most frequent genetic alterations found were 5′-CpG island methylation and allelic loss.     

DNA hypermethylation status of multiple genes in soft tissue sarcomas.

The aberrant methylation of promoter CpG islands is known to be a major inactivation mechanism of tumor-related genes. To determine the clinicopathological significance of gene promoter methylation in soft tissue sarcomas, we examined the promoter methylation status of 10 tumor-related genes in 65 soft tissue sarcomas and 19 adjacent non-neoplastic tissues by methylation-specific PCR. The methylation frequencies of tumor-related genes tested in soft tissue sarcomas were 17 (26%) for RASSF1A, 11 (17%) for DAP kinase, 10 (15%) for MGMT, nine (14%) for GSTP1, eight (12%) for PTEN, six (9%) for p16 and hMLH1, five (8%) for hMSH2, two (3%) for p14, and one (2%) for RB. Promoter methylation of these genes was not recognized in non-neoplastic tissues. All those cases of soft tissue sarcoma that had MGMT methylation, with the exception of one case of malignant peripheral nerve sheath tumor, showed large tumor size (> or = 10 cm) or recurrence. Moreover, eight of 10 cases with MGMT methylation revealed high American Joint Committee on Cancer stage. Seven of 10 cases (70%) with MGMT methylation showed a loss of MGMT expression by immunohistochemistry. In addition, MGMT methylation status had a statistically significant correlation with a loss of MGMT expression (P=0.014). In conclusion, although methylation of tumor-related genes was a relatively rare event in soft tissue sarcomas, methylation was tumor-specific. Of 10 tumor-related genes, cases with MGMT methylation had a tendency to be aggressive behavior. Moreover, MGMT methylation was closely associated with a loss of MGMT expression. Although our findings need to be extending to a large series, promoter methylation of tumor-related genes is likely to have an association with the pathogenesis of soft tissue sarcomas. Furthermore, MGMT methylation may be associated with tumor aggressiveness and the inactivation of MGMT gene.